Title :
Ultrafast All-Optical Flip-Flops, Simultaneous Comparator-Decoder and Reconfigurable Logic Unit With Silicon Microring Resonator Switches
Author :
Sethi, Preeti ; Roy, Sandip
Author_Institution :
Dept. of Phys. & Comput. Sci., Dayalbagh Educ. Inst., Agra, India
Abstract :
We present designs of all-optical SR, clocked-SR, D and T flip-flops, simultaneous single-bit comparator-decoder and reconfigurable logic unit based on all-optical switching by two-photon absorption induced free-carrier injection in silicon 2 × 2 add-drop microring resonators. The proposed circuits have been theoretically analyzed using time-domain coupled-mode theory and all-optical switching has been optimized for ultrafast (~25 ps), low-power operation (~25 mW) and high modulation (> 85%), enabling logic operations at 40 Gb/s. The designs are attractive due to advantages of high Q-factor, tunability, compactness, cascadibility, scalability, reconfigurability, simplicity and minimal number of switches and inputs for realization of the desired logic.
Keywords :
Q-factor; comparators (circuits); coupled mode analysis; elemental semiconductors; flip-flops; high-speed optical techniques; micro-optomechanical devices; micromechanical resonators; microswitches; optical design techniques; optical logic; optical modulation; optical resonators; optical switches; optical tuning; photoexcitation; silicon; two-photon processes; D flip-flops; Q-factor; Si; T flip-flops; all-optical SR; all-optical switching; bit rate 40 Gbit/s; clocked-SR; logic operation; reconfigurable logic unit; silicon add-drop microring resonators; silicon microring resonator switches; simultaneous single-bit comparator-decoder; time-domain coupled-mode theory; two-photon absorption induced free-carrier injection; ultrafast all-optical flip-flops; ultrafast low-power operation; Flip-flops; Optical ring resonators; Optical switches; Probes; Silicon; Ultrafast optics; Optical computing; optical flip-flop; optical logic devices; optical signal processing; ring resonators; silicon photonics;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2013.2295179
